1. Engine Engine Overall Intake & Exhaust System Fuel System
Charging System
Engine Control System

2. Engine Engine Overall Engine Specification -A Model 2UZ-FE (‘03 GX470)
2UZ-FE (‘03 LX470)
No. of Cylinders and Arrangement
8-Cylinder, V type 
Valve Mechanism
32-Valve DOHC Belt & Gear Drive
Displacement
4664 cm3 (284.5 cu in.)
Bore X Stroke
94.0 X 84.0 mm
(3.70 X 3.31 in.)
Compression Ration
9.6 : 1
Maximum Output (SAE-NET)
rpm rpm)]
Maximum Torque (SAE-NET)
rpm rpm)]

3. Engine Engine Overall Engine Specification -A
The major difference from the 2UZ-FE of ‘03 LX470
The carbon filter is used at air cleaner
The number of TWC
Plastic made type fuel tank is used
Quick type fuel cap is used
A no-contact type accelerator pedal position sensor is used
The construction of evaporative emission control system

4. Engine Intake & Exhaust System Carbon Filter
Carbon filter adsorb HC in intake system to reduce evaporative emission
Carbon Filter
(Maintenance-free)
Air Flow
Air Cleaner

5. Engine Intake & Exhaust System TWC Three TWCs are used to meet LEV I

6. Reference Intake & Exhaust System TWC -A Cell Density: 62 cells / cm2
Wall Thickness : mm
Volume : 1307 cm3
Material : Ceramic
Cell Density: 93 cells / cm2
Wall Thickness : 0.09 mm
Volume : 1083 cm3
Material : Ceramic
Noble Platinum Portion

7. Engine Fuel System Fuel Tank
Multiplex layer plastic made type fuel tank is used to comply the LEV II regulations
Front
Cross Section
Outside
Multiplex layer
-HDPE(High density polypropylene) resin fuel tank
-Multi layer (6 layers) construction
Inside

8. Engine Fuel System Fuel Tank Cap
Quick-type fuel tank cap has been adopted to improve usability
-Quick type fuel cap ensures 1/3 turns for open / close
-Tether adoption

9. Engine Charging System Alternator
Compact and lightweight SC (Segment Conductor) type alternator is used
Segment Conductor
Twisted
Joined
A Cross Section Diagram
-Square shape conductor for area expanding for higher performance
-Higher current flow makes higher performance
Stator A
Joined Segment Conductor System

10. Engine Engine Control System ETCS-i-A
Engine
Engine Control System
ETCS-i
Evaporative Emission Control System
Cranking Hold Function
Diagnosis

11. Engine Engine Control System ETCS-i-A
Engine
Engine Control System
ETCS-i
In the new 2UZ-FE engine, the link-less type ETCS-i is used
’03 GX470
ECM
Accelerator Pedal Position Sensor
Throttle Control Motor
Throttle Position Sensor

12. Engine Engine Control System ETCS-i-A
Engine
Engine Control System
ETCS-i
A no-contact type throttle position sensor is used
Reduction Gears
Throttle Control Motor
Throttle Valve
Throttle Position Sensor
Hall ICs
Magnets

13. Reference Engine Control System ETCS-i-A
Reference
Engine Control System
ETCS-i
Two Hall ICs and two magnets are used for throttle position sensor
Hall ICs
Magnets
Throttle Valve

14. Engine Engine Control System ETCS-i-A
Engine
Engine Control System
ETCS-i
Throttle position sensor converts into electric signals the magnetic flux density
ECM
Magnet VC 5 5
VTA2
VTA2
VTA1
Hall ICs
VTA VC
Output Voltage (V)
Output Voltage (V)
ECM E2
VTA2
VTA1
VTA
VTA2 E2
Magnets
Hall IC
Full Close
Full Close
Full Open
Full Open
Throttle Valve Opening Angle
Throttle Valve Opening Angle

15. Throttle Position Sensor-A
Service Point
Engine Control System
ETCS-i
Inspection of the throttle position sensor is discontinued from the contact type
Contact type
No-contact type
(’03 GX470)
Inspection
Inspection
Throttle Position Sensor
VC  E2 : 1.25 – 2.35 k
at 20C (68 F)
Throttle Position Sensor
None
The throttle position sensor can not be inspected

16. Engine Engine Control System ETCS-i-A
Engine
Engine Control System
ETCS-i
A no-contact type accelerator pedal position sensor is used
Magnets
Hall ICs
Accelerator Pedal Arm
Hall IC uses and makes no contact type sensor for better durability

17. Accelerator Pedal Depressed Angle
Engine
Engine Control System
ETCS-i
Accelerator pedal position sensor converts into electric signals the magnetic flux density
VPA
ECM
Magnets
EPA 5
VPA2
VCPA
Output Voltage (V)
VPA2
VPA
EPA2
Hall ICs
Full Close
Full Open
VCP2
Accelerator Pedal Depressed Angle

18. Accelerator Pedal Position Sensor
Service Point
Engine Control System
ETCS-i
Inspection of the accelerator pedal position sensor is discontinued from the contact type
Contact type
No-contact type
(’03 GX470)
Inspection
Inspection
Accelerator Pedal Position Sensor
VC  E2 : 1.64 – 3.28 k
at 20C (68 F)
Accelerator Pedal Position Sensor
None
No contact ,no inspection for electrical circuit
The accelerator pedal position sensor can not be inspected

19. Engine Engine Control System Evaporative Emission Control System
The construction is changed to comply with the LEV-II evaporative emission regulations
To Intake Manifold
Tank Pressure Valve
Vapor Pressure Sensor
Restrictor Passage
Charcoal Canister
Purge Valve
Air Filter
Canister Close Valve
The construction is simpler than the conventional vacuum type

20. Reference Engine Control System Evaporative Emission Control System
Conventional vacuum type
Vapor Pressure Sensor
Tank Pressure Valve
ORVR Valve
To Intake Manifold
Charcoal Canister
From Air Connector Pipe
Canister Close Valve
Pressure Switching Valve
Air Drain Valve
Air Inlet Valve
Purge Valve

21. Engine Engine Control System Evaporative Emission Control System
Location
Purge Valve
Service Port
Tank Pressure Valve
Charcoal Canister
Air Filter
Canister Close Valve
Vapor Pressure Sensor

22. Engine Engine Control System Evaporative Emission Control System
Charcoal canister assembly
Canister Closed Valve
Charcoal Canister
(3.0 liters)
To Fresh Air Line
Tank Pressure Valve
To Intake Manifold
From Fuel Tank

23. *: It will affect the air-fuel ratio control of the engine
Engine Control System
Evaporative Emission Control System
The vapor guide prevents the vapor gas without passing through the activated charcoal
From Fuel Tank
From Fuel Tank
Vapor Guide
To Intake Manifold
To Intake Manifold
Clean air
Include vapor gas*
Absorb vapor gas
With vapor guide
Without vapor guide
*: It will affect the air-fuel ratio control of the engine

24. Engine Engine Control System Evaporative Emission Control System
Tank pressure valve controls the flow rate of the vapor gas from fuel tank to charcoal canister
Tank Pressure Valve
Vapor Gas (From Fuel Tank)
Restrictor Passage
When refueling
(Tank pressure is large)
From
Fuel Tank

25. Engine Engine Control System Evaporative Emission Control System
The restrictor passage prevents the large amount of vacuum that is created during system monitoring from entering the fuel tank
From Fuel Tank
Vacuum
Restrictor Passage
Restrictor Passage
If the large amount of vacuum enters the fuel tank during system monitoring, system monitoring is not performed normally

26. The air filter is maintenance-free
Engine
Engine Control System
Evaporative Emission Control System
The air filter prevents dust and debris in the fresh air from entering the system
To Charcoal Canister
To Fresh Air
The air filter is maintenance-free

27. Service Point Engine Control System-A
Service Point
Engine Control System
Evaporative Emission Control System
If the air filter becomes clogged, the ECM illuminates the MIL and record the DTC P0446
DTC P0446 is detected (Canister Closed Valve close malfunction)
Canister closed valve is OK
The air filter is clogging

28. Engine Engine Control System Evaporative Emission Control System
Stored fuel vapors are purged from the charcoal canister when the purge valve is opened by ECM
To Intake Manifold
ECM
Stored fuel vapors
Duty
Atmosphere
OPEN
OPEN

29. Engine Engine Control System Evaporative Emission Control System
When refueling, the fuel vapors enter to the charcoal canister and they are cleaned
The internal pressure increases
ECM
OPEN
Close
OPEN
The fuel vapors are Cleaned

30. Engine Engine Control System Evaporative Emission Control System
When the initial conditions are met, the ECM introduces a vacuum into the system and monitors system to detect system malfunction
Initial conditions are met
P1’
0 mmHg P1
Fuel Tank Pressure
The ECM monitors the amount of pressure increase in the fuel tank
Value B P2
Value A
Purge Valve
Open
Close
Open
Canister Closed Valve
Close

31. The ECM measures the amount of pressure increase (P1) in the fuel tank
Engine
Engine Control System
Evaporative Emission Control System
System monitoring (Step1)
The ECM measures the amount of pressure increase (P1) in the fuel tank P1
Fuel Tank Pressure
0 mmHg P1
15 secs.
Purge Valve
Close
Canister Closed Valve
Close

32. Engine Engine Control System Evaporative Emission Control System
System monitoring (Step2)
The ECM opens the purge valve and introduces a vacuum into the fuel tank
Fuel Tank Pressure
Open
Purge Valve
Canister Closed Valve
Close

33. The ECM measures the amount of pressure increase (P2)in the fuel tank
Engine
Engine Control System
Evaporative Emission Control System
System monitoring (Step3)
The ECM measures the amount of pressure increase (P2)in the fuel tank
Value B
Fuel Tank Pressure P2
Below value A P2
Value B
5 secs.
Value A
Purge Valve
Close
Canister Closed Valve
Close

34. Engine Engine Control System Evaporative Emission Control System
System leak judgment
P2 Measurement
P2 > Reference Value*
Presumes presence of system leak
P2 < Reference Value*
Judges absence of system leak
*: Reference value is
stored in the ECM
Normal system control
P1 is small
Judges presence of system leak
P1 is large
Judges P1 again (P1’)

35. Judges presence of system leak P1’ is large Repeats judgment
P1’ Measurement
P1’ is small
Judges presence of system leak
P1’ is large
Repeats judgment
The MIL illuminates and ECM stores the following DTCs in its memory
Level of Leak
DTC
Very small, small or medium leak
P0442 and/or P0456
Large leak
P0441, P0442 and P0446

36. Engine Engine Control System Evaporative Emission Control System
VSV monitoring (Normal condition)
Purging
System monitoring
System leak judgment
Purge Valve
Open
Close
Open
Canister Closed Valve
Close
Fuel Tank Pressure

37. Engine Engine Control System Evaporative Emission Control System
VSV monitoring (Purge valve open malfunction)
Engine Starting
When the ECM is measuring the P1 value, the pressure in the fuel tank drops rapidly
Purge Valve
Open
Normal Condition
Canister Closed Valve
Fuel Tank Pressure
Malfunction Judgment
It remains in a constant, slight vacuum state
DTC P0441 is memorized, The MIL illuminates

38. Engine Engine Control System Evaporative Emission Control System
VSV monitoring (Purge valve close malfunction)
No vacuum is introduced
Purge Valve
Close
Canister Closed Valve
Fuel Tank Pressure
Malfunction Judgment
The pressure does not change
DTC P0441, P0442 and P0446 is memorized, The MIL illuminates

39. Engine Engine Control System Evaporative Emission Control System
VSV monitoring (Canister closed valve open malfunction)
It is not possible to completely introduce a vacuum
Purge Valve
Open
Canister Closed Valve
Fuel Tank Pressure
Malfunction Judgment
A slight vacuum is created
DTC P0441, P0442 and P0446 is memorized, The MIL illuminates

40. Engine Engine Control System Evaporative Emission Control System
VSV monitoring (Canister closed valve close malfunction)
A large amount of vacuum is introduced
Purge Valve
Canister Closed Valve
Close
Fuel Tank Pressure
Malfunction Judgment
DTC P0446 is memorized, The MIL illuminates

41. Operates Automatically
Engine
Engine Control System
Cranking Hold Function
Once the ignition switch is turned to the START position, this control continues to operate starter until engine starts
“Start”
“ON”
Ignition Switch
Operates Automatically
Starter
Operate
Stop
Engine starts

42. Engine Engine Control System Cranking Hold Function System Diagram -A
Audio & Illumination
ACC
ACC Cut Relay
Ignition Switch
Starter Relay马达继电器
Engine ECU
(ECM) ST
Park/Neutral Position Switch
THW
Engine Coolant
Temp. Sensor水稳传感器
Starter马达 NE
Crankshaft Position Sensor机油位置传感器

43. Engine Engine Control System Cranking Hold Function
The ACC cut relay cuts off the ACC circuit while engine is cranking to prevent the accessory illumination from operating intermittently
Audio & Illumination
ACC
ACC Cut Relay
Ignition Switch
Starter Relay
Engine ECU
(ECM) ST
Park/Neutral Position Switch
THW
Engine Coolant
Temp. Sensor
Starter NE
Crankshaft Position Sensor

44. Automatically Controlled
Engine
Engine Control System
Cranking Hold Function (Operation)
0.2 sec. or more
: With this system
Ignition Switch
Start
: Without this system ON
ACC Cut Relay
Automatically Controlled
Starter Relay
Judgment
NE Signal
Time

45. Engine Coolant Temp. (C)
Reference
Confidential
Engine Control System
Cranking Hold Function
Judgment of the engine starting
Reference Value!!
900
Engine Coolant Temp.
Judgment Level
Above 0 C (32 F)
Approx. 500 rpm
Below 0 C (32 F)
Approx rpm
Judgment Level (rpm)
500
Engine Coolant Temp. (C)

46. Engine Reference Value!! Confidential Engine Control System
Cranking Hold Function
The maximum cranking time will be changed with engine coolant temp.
Reference Value!!
Max. Cranking Time (sec.)
Engine Coolant Temp.
(°C (°F))
Max. Cranking Time
(sec.)
100 (212)
Approx. 2
0 (32)
Approx. 5
-30 (-22)
Approx. 25 5
Engine Coolant Temp. (C)
When engine coolant temp. is lower, the time limit is longer

47. Engine Engine Control System Cranking Hold Function
If the engine is already running, the ECM will not energize to the starter relay
Start
Ignition Switch ON
Starter Relay
OFF
700 rpm
Engine is already running
NE Signal

48. Driver operates intentionally
Engine
Engine Control System
Cranking Hold Function
If the engine speed becomes 1200 rpm or more while cranking, the ECM turns off a starter relay to prevent starter overrun
Start
Ignition Switch
Driver operates intentionally ON
OFF
Starter Relay
1200 rpm
NE Signal
Time

49. Driver operates intentionally Engine does not start (Problem)
Engine Control System
Cranking Hold Function
When a starter is intentionally operated by the driver, the ECM turns off a starter relay after 30 sec. in order to prevent starter overheating
Start
Ignition Switch
Driver operates intentionally ON
30 sec.
OFF
Starter Relay
NE Signal
Engine does not start (Problem)
Time

50. Engine Engine Control System Diagnosis
To comply with the OBD-II regulations, all the DTC have been made to correspond to SAE controlled codes. Some of the DTC have been further divided into smaller detection area than in the past, and new DTC have been assigned to them.
Example
New DTC
Old DTC
DTC
Detection Item
P0031
Oxygen Sensor Heater Control Circuit Low (Bank 1 Sensor 1)
P0032
Oxygen Sensor Heater Control Circuit High (Bank 1 Sensor 1)
DTC
Detection Item
P0135
Oxygen Sensor Heater Circuit Malfunction (Bank 1 Sensor 1)